Monitoring the condition of the cutting tool using self-powering wireless sensor technologies

Ostaševičius, Vytautas; Jurenas, Vytautas; Augutis, V.; Gaidys, Rimvydas; Česnavičius, Ramūnas; Kizauskiene, Laura; Dundulis, Romualdas

doi:10.1007/s00170-016-8939-z

Cited by 13 publications

(12 citation statements)

References 23 publications

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“…Due to the limitations of current wired sensor systems, and in order to reduce the invasion degree of sensor system into the milling or drilling process and increase flexibility, a series of wireless sensor-integrated systems for rotating cutter have been developed [8]- [23], in which the sensors and other electronic components, such as sensor signal processing module, wireless data transfer module, and power supply module, are all integrated into the tool holder. For the key wireless data transfer module, the common technologies, namely Bluetooth [8]- [11], ZigBee [12]- [14], WiFi [15]- [20], Radio frequency identification (RFID) [21] and sub-1 GHz radio frequency [22], [23], have been adopted to transmit the measured condition data wirelessly to a upper host computer. It can be noted that WiFi is the most widely used transmission method for tool condition monitoring, which has the potential to be competitor of other wireless transmission technologies taking into account of its relatively high transmission speed and long transmission distance.…”

Section: Introductionmentioning

confidence: 99%

Simultaneous Wireless Power and Data Transmission Over One Pair of Coils for Sensor-Integrated Rotating Cutter

Zhu

Tao

2020

IEEE Access

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Tool condition monitoring is becoming particularly important in the cutting process. More and more researchers start to integrate the sensors into the tool holder due to its convenient use and wide applicability. However, it is difficult to transmit out the condition data and supply stable power to the sensor-integrated systems through the traditional wired way as the tool holder is under high-speed rotation in milling or drilling process. In this paper, a novel simultaneous wireless power and data transfer system over one pair of coils for sensor-integrated rotating cutter is presented, and the eddy effect caused by the metal handle that impacts the system performance is solved with ferrite shielding. To transmit out the cutting condition data wirelessly, the synchronous detection and envelope detection technology are employed. Meanwhile, the synchronous rectification technology is adopted to improve the performance of the wireless power transfer. Eventually, the experimental platform has been set up and the cutting tests have also been carried out. The results show that the designed new wireless power and data transfer system over one pair of coils is stable and practical to track and transmit out the condition data of the rotating cutter. INDEX TERMS Tool condition monitoring, rotating cutter, simultaneous wireless power and data transfer, one pair of coils, ferrite shielding.

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Section: Introductionmentioning

confidence: 99%

Simultaneous Wireless Power and Data Transmission Over One Pair of Coils for Sensor-Integrated Rotating Cutter

Zhu

Tao

2020

IEEE Access

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“…Thanks to SPM, it is possible to detect production system failures such as collision, overload, breakdown, and tool wear [3]; and thus, it is contributing to saving costs in manufacturing [4]. In this sense, SPM can increase the competitiveness of a machining process by increasing the utilized tool life and decreasing instances of part damage from excessive tool wear or tool breakage [5].…”

Section: Introductionmentioning

confidence: 99%

“…On the other hand, since the machining of the crankcases is not capable, he or she has to continue with the capability analysis and go one level deeper (feature). The third level (feature) suggests that the machining process is not capable for Hole A and that the process is critical (P CI (4) between 1 and 1.33) for Hole C . Now, the decision maker has to go one level deeper for both sets of product characteristics in order to nd the origin of the capability problems.…”

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confidence: 99%

Monitoring high complex production processes using process capability indices

de-Felipe

Benedito

2017

Int J Adv Manuf Technol

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The increasing demand and the globalization of the market are leading to increasing levels of quality in production processes, and thus, nowadays multiple product characteristics must be tested because they are considered critical. In this context, decision makers are forced to interpret a huge amount of quality indicators, when monitoring production processes. This fact leads to a misunderstanding as a result of information overload. The aim of this paper is to help practitioners when monitoring the capability of processes with a huge amount of product characteristics. We propose a methodology that reduces the amount of data in capability analysis by structuring hierarchically the multiple quality indicators obtained in the quality tests. The proposed methodology may help practitioners and decision makers of the industry in three aspects of statistical process monitoring: To identify the part of a complex production process that presents capability problems; to detect worsening over the time in multivariate production processes; and to compare similar production processes. Some illustrative examples based on dierent kinds of production processes are discussed in order to illustrate the methodology. A case of study based on a real production process of the automotive industry is analyzed using the proposed methodology. We conclude that the proposed methodology reduces the necessary amount of data in capability analysis; and thus, that it provides an added value of great interest for managers and decision makers.

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“…C n = s max s (10) As it can be seen, a process is capable (C n values higher than 1) if the variability of the measured product characteristic (s) is smaller than the maximal allowable one (s max ). Veevers [27] introduced the concept of Viability (V r ) of a process by describing its window of opportunity (w).…”

Section: The Maximal Allowable Standard Deviationmentioning

confidence: 99%

“…The pioner of optimization models of production processes based on quality costs was Taguchi [7], whose principles and theories are accepted as reference models due to the revolution that they supposed to quality methods. In this context, Statistical Process Monitoring (SPM) is rated as a very important area of process control [8], to ensure economic productivity by detecting production failures such as collision or tool wear [9] and is contributing to saving costs in manufacturing [10].…”

Section: Introductionmentioning

confidence: 99%

A review of univariate and multivariate process capability indices

de-Felipe

Benedito

2017

Int J Adv Manuf Technol

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This paper oers a review of univariate and multivariate Process Capability Indices (PCIs). PCIs are used in the industry to quantify how well a process can meet customer requirements. Univariate PCIs describe the capability of one single product characteristic. Multivariate PCIs deal with the multivariate case in which the measures of all multiple product characteristics must be within specication limits to be conforming. When analyzing the capability of processes, decision makers of the industry may choose one PCI among all the PCIs existing in the literature, depending on dierent capability criteria. The aim of the review is to describe, cluster and discuss univariate and multivariate PCIs. This review may help researchers and decision makers to identify univariate and multivariate PCIs that can be used when monitoring univariate and multivariate production processes. On the one hand, the authors of this article suggest using PCIs obtained through the alternative denition for the C pk index when analyzing the capability of production processes, in which the estimation of the proportion of nonconforming parts is rated as crucial. On the other hand, all other multivariate PCIs presented in the literature can be applicable in capability analysis of production processes in which a direct relation to the proportion of nonconforming parts is not needed.

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Monitoring the condition of the cutting tool using self-powering wireless sensor technologies

Cited by 13 publications

References 23 publications

Simultaneous Wireless Power and Data Transmission Over One Pair of Coils for Sensor-Integrated Rotating Cutter

Simultaneous Wireless Power and Data Transmission Over One Pair of Coils for Sensor-Integrated Rotating Cutter

Monitoring high complex production processes using process capability indices

A review of univariate and multivariate process capability indices

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